A NEW ARGININE-SPECIFIC PHOTOAFFINITY LABEL FOR THE EPIDERMAL GROWTH FACTOR RECEPTOR.

Miller, Robert Carey.

January 1982

No description available.

Epidermis -- Growth.

Peptide hormones.

Peptide hormones -- Receptors.

Hormones.

Bedeutung der Rho-GTPasen für desmosomale Adhäsion und Pemphigus-Pathogenese / Role of Rho GTPases for desmosomal adhesion and pemphigus pathogenesis

Spindler, Volker Bernd

January 2009

Die Stabiltät und Integrität der Epidermis beruht zu einem großen Teil auf der intakten Funktion der Desmosomen. Diese fleckförmigen Zellkontakte vermitteln extrazellulär die Haftung zwischen den Keratinozyten durch Desmocadherine und sind intrazellulär über Adaptorproteine im Intermediärfilamentsystem des Zellskeletts verankert. Diese Funktion ist bei der Autoimmunerkrankung Pemphigus gestört, die zu intraepidermaler Blasenbildung durch Akantholyse der Keratinozyten führt. Pemphigus vulgaris (PV) und Pemphigus foliaceus (PF) stellen die beiden Hauptvarianten dar, wobei PV durch Autoantikörper gegen die Desmocadherine Desmoglein (Dsg) 3 und oftmals zusätzlich gegen Dsg 1, PF durch Autoantikörper nur gegen Dsg 1 gekennzeichnet ist. Rho-GTPasen sind zelluläre Regulatorproteine, die das Aktinzytoskelett und verschiedene Zellkontakte beeinflussen. Die vorliegende Arbeit beschäftigte sich mit dem Einfluss von Rho-GTPasen bei der Regulation von desmosomal vermittelter Adhäsion. In einem zweiten Teil wurde die Beteiligung von Rho-GTPasen bei den Pemphigusvarianten PV und PF näher charakterisiert. Für den ersten Abschnitt wurden bakterielle Toxine verwendet, die spezifisch Rho GTPasen aktivieren bzw. inhibieren, während für den zweiten Teil IgG-Fraktionen von PV- und PF-Patienten in Kombination mit aktivierenden Toxinen zur Anwendung kamen. Eine Inhibition der drei Hauptvertreter der Rho-GTPasen in kultivierten Keratinozyten und humaner Epidermis führte zu einer Rarefizierung des Aktinfilamentsystems, zu Verlust von membranständig lokalisiertem Dsg 1 und 3 und zu Zelldissoziation sowie zu verminderter Dsg 1 und 3-vermittelter Haftung von Mikroperlen auf der Oberfläche von Keratinozyten. Die Aktivierung der GTPasen resultierte in vermehrter linearisierter Darstellbarkeit von Aktin und Dsg 3 an den Zellgrenzen und einer verstärkten Dsg-vermittelten Haftung. Pemphigus-IgG führten ebenfalls zu Zelldissoziation und Verlust von Dsg-Immunreaktivität in Keratinozytenkulturen, zu Spaltbildung in humaner Epidermis und zum Verlust der durch Dsg 1 und Dsg 3 vermittelten Adhäsion. Dies ging einher mit einer vermehrten Menge an nicht am Zytoskelett verankerten Dsg 3 und wurde durch eine p38MAPK-abhängige Verminderung der Aktivität von Rho A moduliert. Die Aktivierung von Rho A verhinderte die Ausbildung der Pemphigus-induzierten Effekte nahezu vollständig. Zusammenfassend regulieren Rho-GTPasen die desmosomale Haftung in Keratinozyten. Die Daten zeigen weiterhin, dass Pemphigus-IgG durch eine Inhibition von Rho A diese Regulation beeinträchtigt, was zu Schwächung der Zytoskelettverankerung von Desmogleinen und zu Haftungsverlust und Spaltbildung führt. Somit ist Rho A ein wichtiger Faktor der Pemphigus-Pathogenese und stellt einen Erfolg versprechenden Ansatzpunkt zur Entwicklung neuer Therapieoptionen dar. / Integrity and stability of human epidermis is based on the correct function of desmosomes. These spot-like cell contacts mediate adhesion of adjacent keratinocytes by desmosomal cadherins and are linked via adapter proteins to the intermediate filament cytoskeleton. This function is impaired in the autoimmune disease pemphigus, resulting in intraepidermal blister formation by akantholysis of keratinocytes. Pemphigus vulgaris (PV) and pemphigus foliaceus (PF) are the main subtypes of pemphigus, with PV being characterized by autoantibodies targeting the desmosomal cadherins Desmoglein (Dsg) 3 and in part Dsg1. PF patients develeop autoantibodies against Dsg1 only. Rho GTPases are regulatory proteins which are known to modulate the actin cytoskeleton and different cell contacts. The aim of this thesis was to evaluate the role of Rho GTPases in the regulation of desmosome-mediated adhesion. The second part addresses the involvement of Rho GTPases in the pathogenesis of PV and PF. Toxins served to activate or inactivate specific GTPases in the first part, whereas in the latter part purified IgG fractions of pemphigus patients were used in combination with Rho activating toxins. An inhibition of the three best characterized GTPases in cultured keratinocytes and human epidermis resulted in rarefication of the actin cytoskeleton, loss and fragmentation of membrane-localized Dsg1 and Dsg3 immunostaining, cell dissociation and reduced adhesion of Dsg1 and Dsg3-coated microbeads on the cell surface of keratinocytes. Activation of GTPases led to linearized immunoreactivity of Dsg3 at the cell membrane, pronounced cortical actin staining and strengthened Dsg-mediated adhesion. Similarily to inhibition of Rho-GTPases, Pemphigus IgG caused cell dissociation and loss of Dsg staining in cultured keratinocytes, blister formation in human epidermis and reduction of Dsg-mediated adhesion. These changes were accompanied by a decrease of cytoskeleton-bound Dsg3 and were modulated by a p38MAPK-dependent reduction of RhoA activity. Activation of RhoA blocked the Pemphigus IgG-induced effects. Taken together, Rho GTPases regulate desmosomal adhesion in keratinocytes. Additionaly, Pemphigus IgG interfere with this regulation by inhibition of RhoA, resulting in reduced cytoskeletal anchorage of desmogleins, reduced intercellular adhesion and gap formation. Thus RhoA is identified as an important factor in pemphigus pathogenesis and might eventually serve as a target of new therapy approaches.

Zelladhäsion

Pemphigus

Rho-Proteine

Desmosom

Epidermis

ddc:610

Epidemiologische und molekulare Untersuchungen zur Biofilmbildung in Staphylococcus epidermidis und Staphylococcus aureus / Epidemiological and molecular investigations of the biofilm formation in Staphylococcus epidermidis and Staphylococcus aureus

Cho, Seung-Hak

January 2001

Staphylococcus aureus und Staphylococcus epidermidis gehören zu den häufigsten Erregern nosokomialer Infektionen bei immunsupprimierten Patienten. Gleichzeitig bilden diese Bakterien einen wesentlichen Teil der gesunden Hautflora des Menschen. Bisher ist wenig darüber bekannt, ob es Unterschiede in der genetischen Ausstattung zwischen klinischen und kommensalen Isolaten gibt und welche Faktoren zur Etablierung von Staphylokokken im Hospitalmilieu beitragen. Die Ergebnisse der vorliegenden Arbeit zeigen, daß die Fähigkeit zur Biofilmbildung offensichtlich ein wesentliches Merkmal pathogener Staphylokokken ist. Die Expression dieses Virulenzfaktors ist dabei hochvariabel und hängt von der genetischen Ausstattung der Stämme mit dem für die Biofilmbildung verantwortlichen ica-Operon, bestimmten Umweltfaktoren und dem Einfluß von Insertionssequenzen ab. In einer epidemiologische Untersuchung wurde gezeigt, daß in S. epidermidis das ica-Operon häufiger in klinischen als in kommensalen Stämmen vorkommt. Der überwiegende Teil dieser ica-positiven Stämme bildete phänotypisch einen Biofilm aus. Im Unterschied dazu enthielten alle untersuchten S. aureus-Stämme, unabhängig von ihrer Herkunft, das vollständige ica-Gencluster, wobei jedoch keiner dieser Stämme unter Laborbedingungen einen Biofilm bildete. Durch subinhibitorischen Konzentrationen bestimmter Antibiotika bzw. durch Osmostress ließ sich die Biofilmbildung in 30 Prozent der S. aureus-Stämme induzieren. Ebenso konnte in ica-positiven S. epidermidis-Stämmen die Biofilmbildung dirch diese Umweltfaktoren stimuliert werden. Die Studie ergab auch, daß es einen Zusammenhang zwischen der Biofilmbildung, der Antibiotikaresistenz und dem Vorkommen der Insertionssequenz IS256 gibt. So war IS256 signifikant häufig in klinischen S. epidermidis und S. aureus-Stämmen nachweisbar, während es keinen Unterschied im Auftreten von IS257 zwischen klinischen und saprophytären Isolaten gab. Die IS256-positiven S. epidermidis-Stämme wiesen überdurchschnittlich oft das ica-Operon auf und waren gegen mindestens zwei Antibiotika gleichzeitig resistent. Weiterhin konnte gezeigt werden, daß IS256 an der Phasenvariation der Biofilmbildung in vivo beteiligt ist. Bei einem klinischen S. epidermidis-Stamm, der von einem Patienten mit einer Katheter-assoziierten Harnwegsinfektion isoliert wurde, wurde die Insertion des Elementes im icaC-Gen nachgewiesen, was in einem Biofilm-negativen Phänotyp resultierte. Subkultivierung der Insertionsmutante führte nach wenigen Passagen zur Ausbildung eines Biofilms. Die Nukleotidsequenzierung ergab die vollständige Exzision von IS256 aus dem icaC-Gen einschließlich der duplizierten Zielsequenz von sieben Basenpaaren. Diese Daten stimmen vollständig mit den zuvor in einer in-vitro-Studie erhaltenenen Ergebnissen überein und sie zeigen, daß IS256 die Expression des ica-Operons offensichtlich auch in vivo während einer Infektion beeinflußt. Bei S. aureus konnte in dieser Arbeit ebenfalls eine Phasenvariation der Biofilmexpression nachgewiesen werden. Durch Mehrfachpassagen wurden aus ehemals Biofilm-negativen Einzelkolonien mehrere Biofilmproduzenten gewonnen, die auch wieder zum Biofilm-negativen Phänotyp revertieren konnten. Die DNA-Analyse mittels Pulsfeldgelelektrophorese zeigte, daß es in den varianten Stämmen zu größeren DNA-Rearrangements gekommen war, die neben der variablen Biofilmbildung auch mit Unterschieden in der Expression des alternativen Transkriptionsfaktors SigmaB einhergingen. Die Nukleotidsequenzierung des sigB-Systems ergab in den Varianten mehrere Punktmutationen in den SigB-Regulatorgenen rsbU und rsbW. Dies legt nahe, daß der SigB-Genlokus einer starken genetischen Variabilität unterliegt, die wiederum pleiotrope Effekte auf die Genexpression in S. aureus ausübt. Durch Northern-Blot-Analysen konnte allerdings gezeigt werden, daß die Biofilmbildung in den S. aureus-Varianten nicht mit der veränderten SigB-Expression in Zusammenhang steht. / Staphylococcus aureus and Staphylococcus epidermidis belong to the most frequent causes of nosocomial infections in immunocompromised patients. These bacteria form an essential part of the healthy skin flora of human beings. Little is known, whether there are differences in the genetic equipment between clinical and commensal isolates and which factors contribute to the setup of staphylococci in the hospital environment. The results of the presented work show that the ability to form biofilms is an essential feature of pathogenic staphylococci. The expression of this virulence factor is highly variable and depends on the presence of the ica operon which is responsible for biofilm formation, specific environmental factors and the influence of insertion sequences. In an epidemiological investigation, it was shown that the ica operon in S. epidermidis is more often present in clinical strains than in commensal ones. The predominant part of these ica-positive strains formed phenotypically a biofilm. In contrast, all examined S. aureus contained, independent of their origin, the complete ica gene clusters, while, however, none of these strains formed a biofilm under laboratory conditions. Biofilm formation could be induced by subinhibitory concentrations of specific antibiotics or osmotic stress in 30 percent of the S. aureus strains. Also, biofilm formation could be stimulated in ica-positive S. epidermidis strains through these environmental factors. The study also revealed that there is an association between biofilm formation, antibiotic resistance and the occurrence of the insertion sequence IS256. Thus, IS256 was significantly more often detected in clinical S. epidermidis and S. aureus strains, while there was no difference in the occurrence of IS257 between clinical and saprophytic isolates. Most of the IS256-positive S. epidermidis strains carried the ica operon and were simultaneously resistant against at least two antibiotics. Furthermore, it was shown that IS256 is involved in phase variation of biofilm formation in vivo. In case of a clinical S. epidermidis strain that was isolated from a patient with a catheter-associated urinary tract infection, the insertion of the element in the icaC gene was detected resulting in a biofilm-negative phenotype. Subcultivation of the insertion mutant resulted in biofilm-forming variants after a few passages. Nucleotide sequencing indicated the complete excision of IS256 from the icaC gene including the duplicated target site sequence of seven base pairs. These data are in agreement with the results received in a recent in vitro study and show that IS256 has an influence on the ica-expression during an infection. In this study, phase variation of biofilm formation was also shown in S. aureus. After serial passages, several biofilm producers were derived from formerly biofilm-negative single colonies which could also revert to the biofilm-negative phenotype again. DNA analysis by pulsed-field gel electrophoresis showed that in the variants large DNA-rearrangements took place. In addition to the variable biofilm production, differences in the expression of the alternative transcription factor SigmaB were observed in the variants. Nucleotide sequencing of the sigB system indicated several point mutations in the SigB regulatory genes rsbU and rsbW of the variants. This implies that the SigB gene locus is subject to a strong genetic variability that results, in turn, in pleiotropic effects on gene expression in S. aureus. However, Northern blot analysis revealed that the biofilm formation in the S. aureus variants are not associated with the varying SigB expression.

Staphylococcus aureus

Staphylococcus epidermis

Biofilm

Molekulargenetik

ddc:570

Morphological and structural investigations into C3 C4 and C3/C4 members of the genus Panicum grown under elevated CO2 concentrations

Tipping, Claudia, University of Western Sydney, Hawkesbury, Faculty of Science, Technology and Agriculture, School of Horticulture

January 1996

Three perennial tropical Panicum species were grown under ambient and elevated (900 ppm) carbon dioxide concentrations in especially designed microclimate chambers. The study aimed to investigate the influence of high carbon dioxide concentrations on morphology/anatomy with physiological change among three closely related species possessing distinctly different photosynthetic pathways. The anatomy of the leaf was investigated using light microscopy (LM), transmission electron microscopy (TEM), and graphics image analysis. A suitable schedule for fixation, dehydration and embedding of leaf specimens for both forms of microscopy was developed. The anatomy of the species investigated did not change qualitatively, but there were detectable changes in leaf thickness and tissue proportions of the epidermis, mesophyll and thickened tissues (sclerenchyma, bundle sheath, vascular elements) that differed with species. This study is also relevant to the investigation of the evolution of C4, although species, and the progression involved in plants with characteristics intermediate between those of C3 and C4 species. These intermediate species have been mainly characterized by CO2 exchange and biochemical analysis, but they also display anatomical characteristics in between those of C3 and C4 plants. The evolutionary progression of the C3 to C4 species remains unsolved, although current studies indicate that the evolutionary step was from the C3 plant to the C4. Thus the intermediate C3/C4 plants may not be intermediate in an evolutionary sense and they could be seen as a simple hybridization between a C3 plant and C4 plant. In most of the parameters measured the C3/C4 P. decipiens resembled either the C3 P. tricanthum or the C4 P. antidotale. It may therefore be likened to a physiological chimera rather than to a true intermediate form / Doctor of Philosophy (PhD)

electron microscopy

dehyration

leaf specimens

mesophyll

epidermis

morphology

Microdissection of well defined cell populations for RNA isolation in the analysis of normal human skin and basal cell carcinoma

Edlund, Karolina

January 2005

<p>The human skin provides us with an excellent protective barrier and possesses a remarkable ability of constant renewal. Basal cell carcinoma is the most common type of skin cancer. The aim of this project was to verify results from an earlier study investigating the molecular differences between basal cell carcinoma (BCC) and basal cells of normal human epidermis. In that study microdissection of cell populations from BCC and basal cells of normal epidermis respectively was performed in five cases of confirmed BCC. Following RNA extraction and amplification, a gene expression analysis was performed using a 46 k human cDNA microarray. Comparison of expression profiles showed a differential expression of approximately 300 genes in BCC. An upregulation of signaling pathways previously known to be of importance in BCC development could be observed, as well as a downregulation of differentiation markers, MHC class II molecules, and proteins active in scavenging of oxygen radicals. We wanted to confirm these findings for a number of selected genes, using real time PCR. The focal point of this project was microdissection of cells from BCC and subsequent isolation of RNA. Microdissection based methods offer a possibility of selecting well defined cell populations for further analysis by using a focused laser beam. Initially tests in order to optimize the method were also performed, concerning the dehydration process and choice of slides used in microdissection. Isolation of RNA may, as we experienced, be associated with problems due to destruction of RNA by degrading enzymes.</p>

Skin

epidermis

basal cell carcinoma

microdissection

RNA extraction

Pathology

Patologi

The effects of pathogens on club cell investment in fathead minnows, Pimephales promelas

Pollock, Robyn Jennifer

16 March 2011

Fish skin is a metabolically active tissue that responds quickly to stressors and is the first line of defence against physical damage. Club cells, characteristic components of Ostariophysian fish skin, release their contents into the surrounding water upon rupture (e.g. during predation). These chemical cues act as public information of predation risk. Despite the assumption that club cells evolved under the selective force of predation, studies demonstrated that predation has no effect on club cell investment. Rather, club cell production is stimulated by skin penetrating pathogens and parasites. The experiments in this thesis investigate the responses of fish skin to manipulated pathogen risk. In the first experiment, fathead minnows (Pimephales promelas) were exposed to varying infective risk from two pathogen species that differ in pathogenicity, Saprolegnia ferax and S. parasitica. Although there was no difference in club cell density between fish exposed to the two Saprolegnia species, fish exposed to high concentrations of the pathogens had smaller club cells than those exposed to low concentrations. These results are the first to demonstrate a pathogen effect on the size of club cells. The second experiment investigated whether the physical presence of the pathogen was necessary for an alteration in epidermal parameters or whether Saprolegnia parastitica conditioned water was the only stimulus necessary to evoke a change. Results indicated a lack of treatment effect on club cell density, club cell size or epidermal thickness. The third experiment investigated the timing of club cell changes following a pathogen challenge. Although fish exposed to the Saprolegnia ferax treatment had higher club cell density than fish exposed to the control, there was no difference in club cell density between fish sacrificed on day 3, 6, 9 or 12. A portion of the test population for the third experiment was infected with black spot disease. When analyzed separately, trematode infected fish had smaller club cells than those that were uninfected. In light of inconsistent epidermal responses to pathogen challenges, and comparison with other studies, assessment of environmental stressors and population differences that may affect experimental outcomes and potentially interact with infectious agents is advised.

Pimephales promelas

fathead minnow

oomycete

Saprolegnia

club cell

epidermis

fish

The effects of pathogens on club cell investment in fathead minnows, Pimephales promelas

Pollock, Robyn Jennifer

16 March 2011

Fish skin is a metabolically active tissue that responds quickly to stressors and is the first line of defence against physical damage. Club cells, characteristic components of Ostariophysian fish skin, release their contents into the surrounding water upon rupture (e.g. during predation). These chemical cues act as public information of predation risk. Despite the assumption that club cells evolved under the selective force of predation, studies demonstrated that predation has no effect on club cell investment. Rather, club cell production is stimulated by skin penetrating pathogens and parasites. The experiments in this thesis investigate the responses of fish skin to manipulated pathogen risk. In the first experiment, fathead minnows (Pimephales promelas) were exposed to varying infective risk from two pathogen species that differ in pathogenicity, Saprolegnia ferax and S. parasitica. Although there was no difference in club cell density between fish exposed to the two Saprolegnia species, fish exposed to high concentrations of the pathogens had smaller club cells than those exposed to low concentrations. These results are the first to demonstrate a pathogen effect on the size of club cells. The second experiment investigated whether the physical presence of the pathogen was necessary for an alteration in epidermal parameters or whether Saprolegnia parastitica conditioned water was the only stimulus necessary to evoke a change. Results indicated a lack of treatment effect on club cell density, club cell size or epidermal thickness. The third experiment investigated the timing of club cell changes following a pathogen challenge. Although fish exposed to the Saprolegnia ferax treatment had higher club cell density than fish exposed to the control, there was no difference in club cell density between fish sacrificed on day 3, 6, 9 or 12. A portion of the test population for the third experiment was infected with black spot disease. When analyzed separately, trematode infected fish had smaller club cells than those that were uninfected. In light of inconsistent epidermal responses to pathogen challenges, and comparison with other studies, assessment of environmental stressors and population differences that may affect experimental outcomes and potentially interact with infectious agents is advised.

Pimephales promelas

fathead minnow

oomycete

Saprolegnia

club cell

epidermis

fish

Receptor interacting proteins die Rolle der NF-[kappa]B-Aktivatoren bei der Wundheilung der Haut und der epidermalen Differenzierung /

Adams, Stephanie Caroline Johanna

January 2008

Zugl.: Berlin, Freie Univ., Diss., 2008 / Includes bibliographic references.

Effect of growth factors on T-lymphocyte induced keratinocyte apoptosis

Daehn, Ilse Sofia,

January 2007

Thesis (Ph.D.)--Flinders University, Dept. of Medicine-Biotechnology. / Typescript bound. Includes bibliographical references: (leaves 267-307) Also available online.

Analyse der Cytokin-vermittelten Wachstumsregulation in Homöostase und Wundheilung der Haut : Interleukin-18 in der dermal-epidermalen Kommunikation /

Fritsch, Anja.

January 2004

Universiẗat, Diss.--Jena, 2004.